Abstract

Background

Generalized hypoxic pulmonary vasoconstriction (HPV) occurring during exposure to hypoxia is a detrimental process resulting in an increase in lung vascular resistance. Nebulization of sodium nitrite has been shown to inhibit HPV. The aim of this project was to investigate and compare the effects of nebulization of nitrite and different formulations of acidified sodium nitrite on acute HPV.

Results

In the ex vivo model, nitrite nebulization attenuated HPV and increased nitric oxide concentrations in exhaled gas and nitrite concentrations in the perfusate. The acidified forms of sodium nitrite induced higher levels of nitric oxide in exhaled gas and had longer vasodilating effects compared to nitrite alone. All nitrite formulations increased concentrations of circulating nitrite to the same degree. In the in vivo model, inhaled nitrite inhibited HPV, while pulmonary arterial pressure, cardiac output and blood gases were not affected. All nitrite formulations had similar potency to inhibit HPV. The tested concentration of appeared tolerable.

Keywords

Background

Hypoxia-induced pulmonary arterial vasoconstriction is an important physiologic mechanism leading to redistribution of blood flow from poorly ventilated areas of the lung to better ventilated ones in an attempt to optimize ventilation-perfusion matching [1]. Generalized HPV, which occurs during exposure to hypoxia or at high altitudes, is a pathophysiologic process resulting in an acute increase in pulmonary vascular resistance, right ventricular overload, and restriction of right ventricular function [2]. Chronic hypoxic exposure, which accompanies lung diseases such as chronic obstructive pulmonary disease and pulmonary arterial hypertension, results in sustained HPV and vascular remodeling, which in turn leads to acceleration of right ventricular failure [3]. Therefore, resolution of HPV is a viable strategy for treatment of these patients.

NO is a potent endothelial-derived vasodilating agent [4]. Inhaled administration of exogenous NO has a vasodilatory effect that is selective for the pulmonary vasculature [5]. Moreover, activation of the NO-cGMP signaling pathway has been shown to attenuate HPV [6] and has antiproliferative effects [7].

Recently, nitrite metabolism has gained attention because it may represent an endogenous store of NO [8]. Enzymes having nitrite reductase activity include deoxyhemoglobin [9] and xanthine oxidoreductase [10]. Non-enzymatic NO generation from nitrite under acidic conditions [11] in the stomach or due to reaction with ascorbic acid has also been demonstrated [12, 13]. Further, nitrite reduction to NO in a physiologically acidic environment (pH 6.66) has been shown to relax isolated aortic rings. This effect was augmented in the presence of ascorbic acid [14].

However, the hemodynamic importance of these mechanisms is still subject of debate because the NO-producing activity of deoxyhemoglobin can be overwhelmed by the NO-scavenging properties of hemoglobin [15]. On the other hand, nitrite delivered to the lungs of newborn sheep by nebulization induced NO release and inhibited HPV [16]. Moreover, increased blood flow after nitrite infusion has been demonstrated in humans [17, 18]. Topical administration of acidified nitrite formulations has been shown to increase blood flow in skin [19].

Thus, mammals have both nitrite reducing systems to promote vasodilation and systems capable of blunting this vasodilating effect. The aim of this study was to test whether application of acidified sodium nitrite formulations could inhibit HPV in an ex vivo and in vivo rabbit model and if there are differences in the effects of nitrite alone and acidified formulations. Additionally, we sought to test the possibility of restricting the vasodilating effect of nitrite to the pulmonary vasculature by nebulization of the nitrite formulations [20].

Animals

All animal experiments were approved by local authorities. Male New Zealand White Rabbits (body weight 3.33 ± 0.24 kg) were used. Animals were kept under pathogen-free conditions and handled in accordance with the European Communities recommendations for experimentation.

Isolated lung model

The technique of isolated rabbit lung perfusion has been described [21]. Briefly, rabbits were anticoagulated intravenous administration of heparin 1,000 U/kg and deeply anesthetized with ketamine and xylazine. The lungs were removed from the thorax without interrupting ventilation and perfused and freely suspended from a force transducer for monitoring organ weight in a humidified chamber at 39°C. In a recirculating system, the flow was slowly increased to 100 ml/min (total volume 250 ml). Left atrial pressure was set at 2 mmHg (referenced at the hilum), and the entire system was equilibrated at 37°C.

Pressures in the pulmonary artery and left atrium were registered with pressure transducers, and data were continuously transferred to a computer for online monitoring. Inclusion criteria for the study were 1) a homogeneous white appearance of the lungs with no signs of edema, hemostasis or atelectasis; 2) initial Ppa and ventilation pressure values in the normal range; and 3) a constant organ weight during an initial steady-state period of at least 20 minutes. Figure 1 illustrates the basic design of the experiments.

Figure 1

Timescale ofex vivoexperimental setup. A total of six hypoxic maneuvers (3% O2 in an inhaled gas mixture) were performed. The second hypoxic maneuver was used as a control, because the second and subsequent hypoxic maneuvers induced HPV of stable and reproducible strength. Nebulization was initiated at the onset of the third hypoxic maneuver. In dose titration experiments, nitrite nebulizations were performed beginning with the third maneuver. The concentration that was delivered increased with each subsequent nebulization.

Erythrocyte isolation

During lung preparation, blood was collected by puncturing the left ventricle. After centrifugation for 10 minutes at 300 × g, the buffy coat was removed. The remaining erythrocytes were washed by mixing with Krebs-Henseleit buffer (1:1 ratio) and re-centrifuged. Supernatant was removed, and sedimented erythrocytes were admixed with re-circulating buffer according to the protocol (see Figure 1).

Experimental protocol

After the initial steady-state period, washed autologous erythrocytes were admixed with recirculating buffer to achieve a level of 10% hematocrit. A blood transfusion filter (Pall, Dreieich, Germany) was used to remove erythrocyte aggregates from circulation. After a 50-minute stabilization period, hypoxic challenges were initiated by switching the inhaled gas mixture to a hypoxic mixture of 3% O2, 5.3% CO2, and 94.7% N2 (Messer, Siegen, Germany). In dose-escalation experiments, after the first two hypoxic maneuvers every hypoxic challenge was accompanied by nebulization of sodium nitrite in increasing concentrations. Dosages tested were 1 μg/ml, 10 μg/ml, 100 μg/ml, 1 mg/ml, 5 mg/ml and 10 mg/ml. Dosages were calculated in ALF.

The experimental protocol for testing different formulations is presented in Figure 1. Six sequential hypoxic maneuvers of 15 minutes duration interrupted by 15-minute periods of normoxic ventilation were conducted. During the third hypoxic challenge, nebulization was carried out using the AeronedLab nebulizer system (Respironics, Herrsching, Germany) either with PB (0.05 mM) or different sodium nitrite formulations dissolved in PB.

Nebulization of these formulations of sodium nitrite resulted in nitrite concentrations in ALF of approximately 1 mg/ml. This concentration is based on the volume of ALF in our experimental setup, found to be 2.5 ml [22], and the delivery efficiency of our nebulization system at approximately 25%, estimated by weighing the nebulizer system before and after nebulization.

Measurement of Noex

Measurements were performed as described by Spriestersbach et al. [23]. Briefly, aliquots of exhaled gas were taken continuously for measurement by chemiluminescence using a Sievers 280 NO Analyzer (Seeheim/Ober-Beerbach, Germany).

Measurement of nitrite and nitrate in perfusate

Nitrite in the perfusate samples was measured using Griess reagent according to manufacturer's instructions (Sigma, Munich, Germany). Briefly, perfusate was sampled from venous effluent at the times illustrated in Scheme 1. After centrifugation, the supernatant was aliquoted, frozen immediately, and stored at -20°C until analysis. For measurement of nitrite, 100 μl of perfusate was mixed with 100 μl of Griess reagent. After 15-minute incubation at room temperature, the absorbance at 540 nm was measured. The nitrite concentration in experimental samples was calculated by comparing values against a calibration curve. Calibration curve was generated by serial dilutions of sodium nitrite of known concentrations in the same buffer as used for experiments. To measure nitrite and nitrate levels, samples were incubated with Griess reagent for 10 minutes, and then 100 μl vanadium chloride was added. After 35-minute incubation at 36°C, the absorbance was measured.

Wet to dry ratio determination

At the completion of perfusion experiments, pieces of lung tissue from every lobe were cut. Samples were weighed and dried in an oven at 60°C for 7-9 days until the weight stabilized. Initial weight (wet) was divided by final weight (dry).

Rabbit surgical preparation

Techniques for the measurement of invasive hemodynamics are described elsewhere [24]. Briefly, rabbits were anesthetized with xylazine (2.1 mg/kg) and ketamine (7 mg/kg), followed by a constant intravenous infusion of xylazine (25 mg/kg/h) and ketamine (80 mg/kg/h) (Injectomat S; Fresenius, Bad Hamburg, Germany) through the right peripheral ear vein. Rabbits were anticoagulated with heparin (200 U/kg), tracheostomized and ventilated with an FIO2 of 0.5 using a Harvard respirator (cat/rabbit ventilator; Hugo Sachs Elektronik, March Hugstetten, Germany). Frequency was set at 40 breaths/min, tidal volume at 8 ml/kg, and PEEP at 0.5 mmHg resulting in a paCO2 range of 35-45 mmHg. A catheter was inserted into the left carotid artery and connected to a pressure transducer for arterial pressure monitoring. The right femoral vein was cannulated for infusion of saline. A balloon-tipped pulmonary artery catheter (Berman angiographic balloon catheter AI-07134, 4F; Arrow, Reading, PA) was inserted into the pulmonary artery through the right external jugular vein.

Hemodynamics and blood gases

Ppa and mean Psa were continuously recorded using fluid-filled pressure transducers (Braun; Combitrans, Melsungen, Germany). The level of the left atrium was the zero reference for measurements. CO was calculated by the Fick's principle, employing the mixed venous oxygen content, arterial oxygen content, and oxygen uptake. Oxygen uptake of the animals was measured online (O2 controller; Labotect, Göttingen, Germany). Arterial and mixed venous samples were collected (1 ml) and maintained on ice until analyzed for pO2, pH, and pCO2 (ABL330; Radiometer, Copenhagen, Denmark). Hemoglobin and oxygen saturation were measured using an OSM2 hemoximeter (Radiometer).

Experimental protocol

After the initial steady-state period, hypoxic challenges were initiated by reducing the FIO2 to 0.15. Six sequential hypoxic maneuvers of 15 minutes duration were interrupted by 15-minute periods of normoxic ventilation. During the third hypoxic challenge, nebulization of either PB (0.05 mM) or different sodium nitrite formulations dissolved in PB was performed. Blood samples for gas analysis were drawn during the steady-state period and during hypoxic challenges with ongoing nebulization.

Data analysis

Data are expressed as mean ± s.e.m. For multiple comparisons, one-way analysis of variance followed by a post-hoc test (Student-Newman-Keuls) was used. To evaluate intra-group differences, a paired t-test was used. P values < 0.05 were considered significant.

Results

Nitrite nebulization reduces HPV in the rabbit ex vivo model

Ventilation with 15-minute periods of hypoxia induced acute pulmonary vasoconstriction (Figure 2, 3). All hypoxic challenges, except the first, induced reproducible vasoconstriction. Therefore, the second HPV response was used as a reference. Nebulization of sodium nitrite or vehicle was performed during the third hypoxic challenge, and experiments were complete after the sixth hypoxic challenge. Initial experiments were performed to determine the concentration of sodium nitrite needed for a significant change in Ppa. In these dose escalation experiments, sodium nitrite at both 1 and 10 mg/ml in ALF was found to reduce the HPV response (Figure 2A). However, nitrite at 10 mg/ml induced a significant increase in lung weight during nebulization, suggesting toxicity (Figure 2B) and therefore a dose of 1 mg/ml was chosen for the remaining experiments. Sodium nitrite effectively reduced the strength of HPV, whereas nebulization with PB had no discernable effect on HPV (Figure 3).

Figure 2

Dose titration for nebulized nitrite in the isolated perfused lung model. Nitrite was nebulized in increasing concentrations during hypoxic maneuvers. (A) HPV was calculated as the difference between the maximum Ppa during hypoxia and the Ppa during normoxia. (B) Lung weight gain during nebulization. Lungs were freely suspended from a force transducer for monitoring organ weight in a humidified chamber at 39°C. Weight changes were monitored continuously. Values represent differences in lung weight before and after each nebulization procedure. * p < 0.05 vs. PB.

Figure 3

Effect of nebulized nitrite and acidified forms of nitrite on the strength of HPV in the isolated perfused lung model. The strength of HPV is represented as the difference between the maximum Ppa during hypoxia and the Ppa during normoxia. * p < 0.05 vs. PB.

Acidified preparations appeared to have a more pronounced effect on Ppa compared to sodium nitrite alone. Importantly, a single nebulization of nitrite reduced the strength of HPV by 50.9% ± 8.8%. This effect lasted for three hypoxic challenges. These results indicated that sodium nitrite in acidified preparations may have a more sustained effect on HPV than sodium nitrate alone (Figure 3) as evidenced by significant reductions throughout the last hypoxic challenge (i.e., the entire length of the study).

NOex was monitored after nebulization of the various sodium nitrite preparations. Nitrite nebulization significantly increased the concentration of NOex during nebulization. The combination of sodium nitrite with citric acid or ascorbic acid induced a more pronounced increase in the concentration of NOex compared to sodium nitrite alone (Figure 3A). NOex concentrations remained elevated in all nitrite nebulization groups until termination of the experiment (nitrite group 27.9 ± 1.3 ppb and PB group 17.4 ± 2.1 ppb at the end of experiment, p = 0.009). However, during the hypoxic maneuvers, changes in NOex were similar in all groups (Figure 4B).

Figure 4

Impact of nitrite nebulization on the concentration of exhaled NO in the isolated perfused lung model. (A) Exhaled NO was monitored online from the exhaled gas mixture. (B) Hypoxic challenges induced a rapid and reversible decrease in NOex. Nitrite nebulization increased NOex during the hypoxic phase. Values represent the difference between NOex concentrations during hypoxia and during the preceding normoxic phase. * p < 0.05 vs. PB, # p < 0.05 vs. nitrite.

Nitrite nebulization resulted in a rapid increase in nitrite and nitrate concentrations in recirculating buffer (Figure 5), whereas PB nebulization did not. Different formulations of sodium nitrite increased the nitrite level in perfusion buffer to the same extent. Nebulization of sodium nitrite from these formulations did not alter fluid retention in lungs, as assessed by the absence of changes in the wet to dry ratio (Figure 6).

Figure 5

Changes in nitrite and nitrite/nitrate (NOx) concentration in perfusate after nebulization. Perfusate samples were collected as depicted in Scheme 1. Samples were immediately frozen and stored at -20°C until analysis. Measurements were performed using a modified Griess reagent according to manufacturer's instructions. (A) Changes in nitrite concentration in recirculating perfusate. (B) Changes in NOx concentration in perfusate.

Figure 6

Impact of nitrite nebulization on lung wet to dry ratio. At the end of each experiment, pieces of lung tissue from every lobe were cut. Samples were weighed and dried in an oven at 60°C for 7-9 days until the weight stabilized. Initial weight (wet) was divided by final (dry) weight.

Nitrite nebulization reduces HPV in vivo

A second series of experiments was performed in lungs of live rabbits. All rabbits demonstrated stable hemodynamics during experiments without the need for support with adrenomimetics. We chose a level of hypoxia that induced pronounced HPV without significantly changing Psa. Hypoxic maneuvers induced a rapid decrease in paO2 from 260.7 ± 3.6 mmHg to 45.1 ± 1.8 mmHg. Results were similar in all groups. SaO2 decreased from 99.7 ± 0.01% to 86.5 ± 1.6%. This induced acute and reversible HPV (Table 1), which was accompanied by a slight decrease in Psa. Nebulization of sodium nitrite and its acidified forms effectively reduced HPV to one-third of its initial value (Table 1). In groups receiving nebulized sodium nitrite, the strength of HPV during subsequent hypoxic challenges remained slightly reduced.

Table 1

The effect of nebulized nitrite and acidified forms of nitrite on the strength of HPV, Psa and CO in the in vivo model of catheterized rabbits.

PB

PB + nitrite

PB + nitrite + citrate

p value

HPV

Baseline

(mmHg)

1.24 ± 0.58

1.56 ± 0.38

1.79 ± 0.50

n.s.

Nebulization

(mmHg)

1.36 ± 0.50

0.52 ± 0.39

0.69 ± 0.72

p < 0.05

(% of baseline value)

119.52 ± 36.74

32.28 ± 26.13

36.30 ± 51.32

p < 0.05

Systemic hypoxic hypotension

Baseline

(mmHg)

-6.78 ± 1.97

-6.07 ± 0.64

-7.39 ± 2.61

n.s.

Nebulization

(mmHg)

-6.36 ± 1.27

-5.28 ± 1.39

-8.16 ± 0.85

n.s.

Cardiac output

Baseline

(ml/min)

617.63 ± 15.96

725.64 ± 39.59

575.46 ± 34.64

n.s.

Nebulization

(ml/min)

556.79 ± 37.62

589.46 ± 33.28

533.05 ± 28.16

n.s.

HPV was calculated as the difference between the maximum Ppa during hypoxia and the Ppa during normoxia. For percentage calculations, the strength of HPV during the second hypoxic challenge was set to 100%, and the value of HPV during nebulization was related to it. Nitrite alone and in acidified forms nebulized during the third hypoxic maneuver significantly inhibited HPV. CO was measured by Fick's method. Blood samples for analysis were drawn during normoxia and at the end of the third hypoxic challenge. Psa was monitored continuously using a catheter placed in the left carotid artery. Values represent the difference between Psa during normoxia and Psa during subsequent hypoxia.

Notably, nitrite nebulization did not influence Psa and did not augment hypoxia-induced decreases in Psa. However, acidified nitrite slightly, but not significantly, augmented hypoxia-induced decreases in Psa during the third hypoxic maneuver (Table 1). CO was comparable in all groups. Sodium nitrite nebulization did not affect CO (Table 1).

Discussion

We sought to test whether inhalation of acidified sodium nitrite formulations could reduce the extent of hypoxia-induced vasoconstriction. Further, we examined whether acidified formulations had more pronounced vasodilatory effects than nitrite alone as a result of the synergistic action of two different nitrite-reducing mechanisms. The main finding of our study is that both nebulized nitrite alone and acidified formulations effectively reduced the strength of HPV in both ex vivo and in vivo models of acute HPV.

Hunters et al. observed increased NOex and reduced HPV after nitrite nebulization in lambs [16]. These data suggest that inhaled application of nitrite induces preferential vasodilation in the pulmonary circulation, operating via deoxyhemoglobin oxidation by nitrite with NO generation, a mechanism described by Doyle et al. [25]. However, Deem et al. demonstrated that, although this mechanism is operational during hypoxia, its effect is overwhelmed by the NO scavenging property of hemoglobin [15]. These findings suggest limited efficacy of the mechanism of nitrite reduction by deoxyhemoglobin for the treatment of patients. On the other hand, nitrite reductase activity of other enzymes expressed in the lung, for instance xanthine oxidase and mitochondrial respiratory chain, has been described [26]. Combined, these findings could represent an important mechanism responsible for nitrite-induced vasodilation.

Recently, a non-enzymatic pathway of NO generation, resulting from nitrite dysproportionation under acidic pH during anoxia, has gained attention [27]. The highest yield of NO production in anoxic myocardium was found to occur at pH 5.5 [28]. Moreover, topical administration of acidified nitrite formulations induced local vasodilation, presumably resulting from enhanced NO generation [19]. NO generation at acidic pH was potentiated in the presence of ascorbic acid, which led to greater vasodilation.

In accordance with the findings of other investigators, we observed that nebulization of nitrite to ventilated rabbit lungs during hypoxic challenge significantly reduced HPV. Inhibition of vasoconstriction was associated with increased NOex during nitrite nebulization.

The combination of nitrite and citric acid or citric acid and ascorbic acid resulted in acidic formulations with pH values of 5.3-5.4. This pH range was chosen to achieve the maximal rate of non-enzymatic NO generation. The acidification of nitrite solutions led to spontaneous NO generation in vitro (data not shown), in accordance with the mechanism of nitrite dysproportionation described by Zweier et al. [27]. Nebulization of the acidified nitrite formulations to isolated lungs induced a more pronounced increase in NOex than the solution of nitrite alone. Further, acidified formulations induced longer-lasting vasodilation than nitrite alone, although they reduced HPV to the same degree as sodium nitrite. Notably, nitrite nebulization induced a dramatic increase in NOex lasting for 10 minutes. Levels of NOex remained elevated until the termination of the experiment in all nitrite nebulization groups.

Nebulization of nitrite led to a rapid and sustained increase in nitrite concentration in recirculating buffer. The maximum concentration of nitrite in the buffer was 71.3 ± 7.0 μM, which is within the range of effective vasodilating concentrations of nitrite described by others [14, 29, 30]. Higher concentrations of circulating nitrite (as achieved by nebulization) induced lung weight gain. The physiological significance of the elevated level of nitrite in the buffer is not clear. It could represent a depot that delivers and releases nitrite on demand. Conversely, according to the mechanism described by Doyle et al. [25], subsequent hypoxic challenges should lead to deoxygenation with deoxyhemoglobin formation, a process that converts nitrite to NO. Indeed, we observed that in all subsequent hypoxic challenges HPV was slightly lower, although this reduction did not reach statistical significance. However, enhanced NOex, as a result of reaction between sodium nitrite and deoxyhemoglobin during hypoxic maneuvers, was not observed (Figure 3B).

Using the 1 mg/ml formulations, significant fluid accumulation in the lung after nitrite nebulization was not observed, suggesting that nitrite in the concentration used in this study had no adverse effect on the lung.

In the in vivo experiments, sodium nitrite nebulization effectively reduced the strength of HPV in the first hypoxic challenge following nebulization. The effect of both sodium nitrite alone and acidified nitrite formulations lasted for only 15 minutes, although HPV remained slightly reduced during subsequent hypoxic challenges until termination of the experiment. CO did not change significantly during the nitrite nebulization experiments. In contrast to intravenous injection of nitrite, which induces both pulmonary and systemic vasodilation [31], nebulized sodium nitrite induced vasodilation in the lung with no appreciable effect on systemic hemodynamics. However, nebulization of acidified formulations of nitrite slightly augmented hypoxic vasodilation of systemic vessels.

In summary, we observed higher levels of NOex in experiments involving acidified nitrite nebulization. However, we did not observe further enhancement of the HPV-inhibiting effect. Notably, we observed slightly more systemic vasodilation in the acidified nitrite group. However, this effect did not reach statistical significance. Nevertheless, this could be an important consideration in patients suffering from pulmonary hypertension who have limited cardiac reserve and borderline systemic hypotension. One possible explanation is that acidified nitrite is not as dependant as non-acidified nitrite from the local microenvironment and deoxyhemoglobin formation. Therefore, the effects of acidified nitrite formulations may be not restricted to the hypoxic areas of the lung.

We used the ex vivo model of isolated perfused rabbit lung for dose calibration and pharmacokinetic studies. The limitation of this model is that pharmacokinetic and pharmacodynamic data obtained in this manner do not reflect the influence of metabolism and excretion by kidney and liver. Indeed, in our in vivo model we observed a shorter duration of the inhibitory effects of nebulized nitrite on HPV. This may reflect different pharmacokinetics in vivo. Nevertheless, our results obtained from the in vivo model demonstrate that the mechanism described is operational in vivo and has physiological relevance.

Conclusions

In the isolated lung preparation, both of the acidified nitrite formulations we used, as well as nitrite alone, effectively and similarly attenuated HPV with a trend toward a more sustained effect with acidified formulations. NOex increased when nitrite was prepared in an acidic buffer, suggesting a potential means for better efficacy. The concentrations of nitrite we tested appeared tolerable. Nebulization of the nitrite or acidic nitrite formulations preferentially induced vasodilation of the pulmonary vasculature with no appreciable effect on systemic arterial pressure or cardiac output in vivo.

Copyright

This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.